Abstract
Worldwide, bees are the most important group of animal pollinators. The ecosystem service they provide is vital in natural areas and croplands, and the taxonomic and functional diversity associated with bees is vital in understanding ecosystem functioning ensuring biodiversity conservation, food security and human livelihoods. A dataset of bees from mountainous areas of Carajás National Forest (eastern Amazon) and Nova Lima (Atlantic Forest) is presented here. It is a compilation of sampling efforts from 1983 to 2018 through the accession of data stored in museum collections. In total, 222 and 144 bee species were recorded in Carajás and Nova Lima, respectively. This represents the most robust dataset of Brazilian bees including species traits (body size, flight range, distribution, crop pollination, sociality and nesting) of 328 species. This dataset contributes to advances in the knowledge of the functional trait ecology of wild bees and can benefit further studies that analyze the response of wild bees to land use and climate changes, and its effects on the provision of crop pollination services.
Measurement(s) | Trait • Ecology |
Technology Type(s) | digital curation |
Factor Type(s) | site |
Sample Characteristic - Organism | Hymenoptera |
Sample Characteristic - Environment | tropical broadleaf forest biome |
Sample Characteristic - Location | Brazil |
Machine-accessible metadata file describing the reported data: https://doi.org/10.6084/m9.figshare.12053742
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Background & Summary
Among insects, bees are the main pollinators for the majority of plants, being essential in both natural and crop environments for the provision of pollination services and for ensuring global food security to human population1,2. Additionally, these insects can be used as a means to improve human livelihoods, biodiversity conservation, and scientific, cultural and recreational development in natural, agricultural or urbanized landscapes3,4. In fact, the economic value of pollination services can be estimated for agricultural areas5,6. When considering natural areas, however, this value may be difficult to estimate, but this ecosystem function does influence local environmental quality, species conservation and the supply of native pollinators to crop fields7,8,9,10. Nevertheless, a global pollinator decline has been reported, mainly for managed species (e.g., Apis mellifera L.), but also for wild species (e.g., other bees, birds and bats)11, which directly affects the worldwide provision of pollination services12.
Planetary decline and non-random loss of biodiversity have been reported in response to anthropogenic-driven actions13. Factors implicated in bee species decline include habitat loss due to landscape change, competition with invasive species for resources, emergent species (including pathogens), pesticides and climate change12,14,15,16. Linking ecosystem functioning to biodiversity conservation is fundamental in determining the aims of policies and strategies for species and ecosystem conservation in the long term17. In this context, the use of functional traits has arisen as a direct means of addressing the abovementioned link18,19 (Fig. 1).
Pollination success is related to pollinator species occurrence and availability16, but it also depends on the biological community assembly17,20,21,22 and on the relationship between flower traits (e.g., size and morphology) and the body size of its visitors23. Castilla et al.24 showed that pollinator body size contributes to plant seed viability but is apparently not related to long-distance genetic flow. Furthermore, pollination is a mobile agent-dependent ecosystem function that directly relies on the flight range capability of the pollinator agent25. For bee species, a positive relationship between body size and flight range has been well documented26,27, and foraging distance can determine the spatial scale within the landscapes at which bees are able to visit flowering plants28,29 (Fig. 2).
Ecosystem functioning relies mostly on a species’ ability to perform vital ecosystem functions30, and functional traits are the species characteristics that link them to their ecological function31. Bees are the major pollinator of plants because they directly depend on the supply of food provided by flowers (pollen and nectar)32. Floral rewards, however, are not the only requirement of bees to endure in the environment; they also require a nesting substrate and favorable landscape and climatic conditions15,33. Thus, our aim is to provide a database of species traits for Brazilian bees that are of significance to ecology and conservation29,34,35. Some important traits that explain bee community structure include body size, flight range, sociality, nesting location, nest behavior and diet29,34,35.
Here, we compiled a dataset of bee species from the Brazilian iron-rich mountains located in the Amazon (Pará State) and Atlantic Forest (Minas Gerais State). The dataset contains records of bees collected from 1983 to 2018 but in disconnected time frames. It represents one of the most comprehensive and robust datasets of bee species from Brazil and a unique dataset of bee species (including functional traits) from the Amazon forest, encompassing nearly 80% of the bee fauna from the eastern Amazon36. A total of 328 bee species records are provided here37. For those species, the following ecological traits are presented: body size, flight range, Neotropical distribution, crop pollination records, sociality and nesting substrate (Fig. 1).
Methods
Sites
Carajás national forest
The Carajás National Forest (05°52′S–06°33′S, 49°53′W–50°45′W) is located in the southeastern portion of Pará State, Brazil (Fig. 3a). Carajás is an Amazonian domain area, mainly covered by forest formations38,39. It is located at an altitudinal range of 700 to 800 meters above sea level. The climate in this region is characterized as rainy tropical with winter drought (AWi), according to Koppen’s classification, with an annual precipitation range of more than 2000 mm and a well-defined drought period from June to September. The average temperature ranges from 25° to 26 °C, but the absolute recorded values range from 15 °C, from July to October, to 38 °C in the remaining months of the year. The predominant vegetation cover is evergreen ombrophilous forests; however, there are also areas of stationary vegetation with different degrees of deciduousness39. The largest Brazilian mineral extraction project is located in Carajás and deals primarily with the extraction of iron ore but also other minerals. It was initiated in the late 1980s and remains active to the present date.
Nova lima
Nova Lima is a Brazilian municipality in the state of Minas Gerais (Fig. 3b). Located in a mountainous landscape surrounded by the Serra do Curral and Serra da Moeda (altitude range: 900 to 1400 m), it is part of the region denominated as the “Plateaus and Mountain ranges of the East-Southern Atlantic” and is mainly composed of metamorphic rocks. The climate is hot and temperate and is classified as Cfa (subtropical humid climate). The average rainfall is 1390 mm per year, with August being the driest month and December the month with the highest precipitation. The average temperature is 23 °C; January is the warmest month of the year, and the lowest temperature occurs in June, i.e., an average temperature of 17.6 °C. The area of the municipality is 430 km2, and the population is estimated to be 92,000 inhabitants with a 0.8 HDI (human development index) (Brazilian Institute of Geography and Statistics - IBGE). The region has intense mineral extraction activities, including the mines of Morro Velho, Mostardas and Rio de Peixe, in addition to the recently closed mine of Águas Claras; the most important minerals are iron and gold. The city of Nova Lima integrates the metropolitan region of the state’s capital, Belo Horizonte (with approximately 2.5 billion inhabitants).
Experimental and sampling design
The list of bee species names was obtained from two Brazilian entomological collections as the main repositories for specimens collected in both Carajás and Nova Lima, i.e., the Museu Paraense Emilio Goeldi (MPEG) entomological collection and the Universidade Federal de Minas Gerais (UFMG) entomological collection. Neither of these collections have online databases. Specimens of both collections were validated by specialists (for specimens’ IDs see37). Therefore, our dataset contains those records whose specimens were located and certified by specialists for both collections37.
At MPEG, we found bees from Carajás that were collected in the Serra Norte area (Fig. 3a) from 1983 to 2018. At UFMG, we found bees from Carajás that were collected in the Serra Norte and Serra Sul areas (Fig. 3a) during the 2008 to 2017 period. Bees from Nova Lima (Fig. 3b), collected from 1998 to 2017, were found only at UFMG. Bees were mainly collected with the use of entomological nets (active search), odoriferous traps (for male orchid bees, tribe Euglossini) and flight interception traps (malaise). Sampling efforts were not standardized, as a number of different researchers conducted their field work at these locations to answer several unrelated questions.
A total of 328 bee species have been recorded in these two areas, corresponding to more than 20% of the estimated 1500 bee species recorded in Brazil40. A total of 222 species were recorded in Carajás, representing nearly 80% of the bee fauna in Pará State, eastern Amazon (the 2nd largest Brazilian state and the world’s 13th largest state)36. More than 30% of these species are social (mostly the Meliponini tribe, but also the Bombini and Apini tribes), nesting mainly in pre-existing cavities (47%) or in the ground (22%), and 33% of these bees (at least at the generic level) have been identified as crop pollinators. A total of 144 species were recorded in Nova Lima, representing 65% of the bee fauna in Minas Gerais State (the 4th largest Brazilian state)36. Nearly 80% of these species are solitary, more than 50% nest in the ground and 37% have been reported to be pollinators of Brazilian crops.
Although extensive sampling efforts were previously carried out in these areas, our dataset does not represent a final list but rather the consolidation of past sampling efforts together with species traits that are of great importance for ecological analysis and pollination services valuation10. New field sampling strategies are currently being carried out, following standardized methodology, to equalize sampling efforts and provide future comparison. Further steps will include a better understanding of the ecological functioning in these areas, with practical implications for the ecological restoration of mine-land rehabilitated areas in the Amazon Forest. Additionally, bee taxonomy for the Neotropical region is not complete, and recent taxonomic reviews continue to reveal new species, mainly from the less studied and most speciose areas, such as tropical rain forests36,41,42.
From this large dataset, it will be possible to answer more complex questions on the functioning of these ecosystems, such as the importance of the bees in each of these environments, the value of the ecosystem services they may provide and how these species will respond to ongoing global changes. Our database adds a robust set of trait-based information for Brazilian wild bees. We apply techniques that were previously reported in the literature9,10,24,26,27 and that are necessary for the advancement of functional ecology and the understanding of wild bees and their role in crop pollination and the provision of ecosystem services28,29.
Traits acquisition and laboratory research methods
Body size, size classes and flight range
Bees from the two abovementioned entomological collections were analyzed under a stereomicroscope coupled with a calibrated micrometric ocular. Body size measurements were based on the bees’ intertegular distance (hereafter ITD) (Fig. 4i). We measured up to five specimens of each species and the average value was calculated37. ITD measures represent the mesoscutum width of each bee species, which is the body section where the alary muscles are located. Bees with a larger ITD have been shown to be able to fly longer distances across landscapes26. The estimation of the flight distance of each bee species was calculated from the ITD measurement and taxonomic position using equations presented in27. Flight range estimations were based on models generated from previous on-site experiments for both social43,44 and solitary bees45,46. Recorded flight range experiments used two standard methodologies: (1) the release of marked bees at known distances from their nests and their recapture at the nest entrance (homing distance), considering the maximum homing distance (mhd – 90% return rate) and typical homing distance (thd – 50% return rate) and (2) feeder training techniques, which record the maximum energetically profitable foraging distance for a bee to forage at an artificial feeder (maximum foraging distance – mfd) and the distance to which bees stop recruiting nest mates to an artificial feeder (maximum communication distance – mcd)26.
We classified bees into three body size categories according to their ITD measures: small, medium and large (Fig. 4a). As body size and flight range are positively correlated, our body size categories also indicate maximum flight range, being up to 1 km for small bees, up to 5 km for medium bees and up to 30 km for large bees (Fig. 4b). Body size categories were established using the body size of bees in the genus Melipona Illiger as a standard for the medium-size class. Thus, ITD measures for the medium-size class ranged from 2.2 to 3.9 mm, with 2.2 mm being the ITD of Melipona amazonica Schulz, 1905, the smaller Melipona species in our dataset, and 3.9 mm being the ITD of Melipona fuliginosa Lepeletier, 1836, the larger Melipona species in our dataset. Bees with an ITD smaller than 2.2 mm were classified as small (e.g., Trigonisca, Plebeia and Augochlora), and bees with an ITD larger than 3.9 mm were classified as large (e.g., Xylocopa, Centris and Eulaema). Although arbitrary, our body-size classes are related to the fact that Melipona bees are commonly known as medium-sized bees.
Additionally, our classes agree with those previously established in other papers24,47,48,49,50 although some of those papers did not include Melipona bees. Therefore, we believe our classification is an appropriate standard for size classification of bees worldwide. To date, ours is the most species-rich dataset, which represents five bee families (Apidae, Andrenidae, Colletidae, Halictidae, Megachille) and includes the widest range of body size measurements reported. For example, the dataset includes the very large species Xylocopa frontalis (Olivier, 1789) (ITD = 8.4 mm) and also the minute Trigonisca variegatifrons Albuquerque and Camargo, 2007 (ITD = 0.6 mm).
Taxonomic ranks, known distribution, distribution area, new record, locality and location of measured specimens
Information on the taxonomic ranks (family, tribe, genus, subgenus, specific epithet, scientific name authorship) and known Neotropical distribution of each species were acquired using the online version of Moure’s bee catalog (available at http://moure.cria.org.br). Additionally, we searched and included updated information from the literature (after 2014, which was the last catalog update) when available. We chose to use Michener’s32 family classification instead of that provided in the catalog, as this classification is mostly used in other regions of the world besides Brazil. We included new occurrence records for all the specimens collected out of the known distribution provided in the Moure’s bee catalog.
Locality represents where each species was collected in our study sites. Localities from Carajás National Forest are Bocaina and Canaã dos Carajás from Serra Sul area and Carajás and Parauapebas from Serra Norte area. Remaining bee species were collected in Nova Lima.
Location of measured specimens indicate in which entomological collection (MPEG or UFMG) we found and measured the specimens collected at our study sites. For each of the specimens measured at the entomological collections (MPEG and UFMG) we provide the complete label information as well as specimen ITD measure37.
Crop pollination
Information on crop pollinator species was obtained from the database published by Giannini et al.51, which includes an extensive assessment of crop pollinators in Brazil. This database contains all the published interactions recorded between Brazilian crops and their pollinators, including the information source and the type of interaction recorded (effective, occasional or potential pollinator or simply a visitor).
In our dataset, we specify which species are known crop pollinators and also, for each bee species we specify which crop they were reported to pollinate37. Knowledge of crop pollinators is of great importance, not only in ecology and ecosystem functioning, but mainly for directing conservation strategies and policy decision making for ensuring food security. This knowledge can also be used as a means to evaluate ecosystem services provided by bees, to understand landscape population structure and to establish management and conservation strategies for individual species.
Sociality and nest location
Sociality and nest location data for each species were acquired by consulting previous natural history or review articles on these subjects. Primarily, a search for natural history data was performed for each species. For those species that completely lack natural history information, we searched for subgeneric information (when available), and when this information was not available, we included generic and tribe natural history information for the particular species. In all cases, before using generic, subgeneric and tribe information, a search in the specific literature was performed to verify the variation level in natural history traits for the specific clade.
We found sociality and nesting information for all species except some Euglossa Latreille, 1802 species. For 23 of the 43 Euglossa species, we did not find natural history data. Natural history traits vary widely within this genus, and the use of subgeneric or generic classification is not applicable for Euglossa species.
We provide the accuracy level of the information provided (i.e. tribe, genus, subgenus, species) and the reference papers from which natural history information was gathered for each species. The references are in the following format: authors, year, article title, journal, journal volume and pages37.
Data Records
The complete database of species records, traits, measured specimen’s information and crops pollinated consists of 3 different files with descriptive names (Table 1). Files are all in ‘.csv’ (Unicode UTF-8) format and are stored in figshare37. Rows represent unique species records, and columns represent the variables provided (Online-only Table 1). For the 328 species, we present 438 trait records, 1530 specimens’ records and 932 crop pollination records. The dataset includes data for all five extant Neotropical bee families belonging to 77 genera.
We measured body size (from ITD, in millimeters) and categorized the mean species data into three body-size classes (small, medium and large).
Flight range, represented as the mhd, thd, mfd and mcd, was calculated from ITD using previously published flight distance estimation formulas26,27.
Specimens from two Brazilian entomological collections (MPEG and UFMG) were measured, and their location (Bocaina, Canaã dos Carajás, Carajás, Nova Lima and Parauapebas) was obtained from the specimen labels37.
The Neotropical distribution was obtained from Moure’s bee catalog (moure.cria.org.br). For species not included in the catalogue we used literature data and information from specimen’s labels. We provide new occurrence records from the specimens measured.
Crop pollination information was obtained from published plant-pollinator interactions compiled by Giannini et al.52 and is represented as yes (crop pollinator species) or no (not previously reported as a crop pollinator) in the traits file. We provide the reported interactions (each pollinated crop) for 106 bee species that pollinate 64 crops37.
Sociality and nesting information were obtained from 63 sources. Three categories of sociality were used: Cleptoparasitic; Eusocial; Solitary. Intermediary sociality classifications were not included as they would require further discussion and explanation, and this information is not the focus of this paper. All pillaging solitary bees (optional or obligate) were included as cleptoparasitic. Only eusocial bees (Apini, Bombini and Meliponini tribes that present obligatory cooperative brood care, division of labor, overlapping generations and reproductive castes) were considered Eusocial. The cleptoparasitic stingless bee genus Lestrimelitta Friese, 1903, was considered Eusocial. All the remaining species with different degrees of sociality were considered solitary. The level of accuracy for the acquired nesting and sociality information is provided based on the taxonomic rank for which the information was found available, being tribe, when information was found only for the species tribe, genus when information for the species genus was found, subgenus when information for the species subgenus was found and species when information for the species was found. Species with no available information, or when high taxonomic level information is not applied, are marked NA.
Nest location categories were based on the following ten classes:
1. ant – species that nest in association with a pre-existent ant nest;
2. cavity – species that nest in a pre-existent or excavated cavity in tree trunks or branches;
3. cavity/human-made – species that nest in a pre-existent or excavated cavity in human-made structures such as walls, bricks and fences;
4. exposed – species with exposed nests that are constructed around tree trunks or branches or around human-made structures;
5. exposed/cavity – species that nest in exposed areas and in cavities;
6. soil – species with subterranean nests in excavated or pre-existent cavities belowground;
7. soil/cavity/human-made – species that nest belowground and in pre-existent natural or human- made cavities;
8. soil/cavity/termite – species that nest belowground, in pre-existent cavities or in association with termite nests;
9. soil/termite – species that nest belowground, in association with subterranean termite nests;
10. termite – species that nest in association with pre-existent termite nests.
Technical Validation
In our dataset we provide the list of bees from Carajás and Nova Lima that have been identified to species level by specialist taxonomists at both MPEG and UFMG entomological collections. This dataset is a compilation of the bee species collected in a long time frame in this areas (for sampling data see Borges et al.37). Locality and id (label data and entomological collection IDs) of measured specimens are provided to ensure they can be revisited. All measures were made by the same individual in order to reduce error. Information from literature was double checked and all sources are provided. For all available species we measured the ITD of up to five specimens in order to include intraspecific variation into our species body size measurements.
For estimating error rates, we manually re-collected data of 568 specimens from 122 species of our dataset (Supplementary Table 1). We found ITD measures differences on 26 out of the 568 specimens re-measured, which represents an error rate of about 4.5%. Errors varied from 0.1 to 0.5 mm; however, almost 70% of errors were distributed between 0.1 and 0.2 mm, which did not produced changes on average values. All the data for each specimen is provided (Brazilian_bees_specimens_data.csv37). We performed automatic and manual corrections and validation procedures for each dataset. All validation files, procedures and scripts are provided in Padovani and Borges52.
Usage Notes
Note that ITD measures are presented as a medium value. We did this as a means to provide a representative value for the species, but a small intraspecific variation can also be found (see Brazilian_bees_specimens_data.csv37). Measured specimens’ data is provided ensuring the access to the individuals used in this database.
Traits regarding sociality and nesting location are all based on previously published papers. Note that for some species we rely on generic or subgeneric information in our database, so this can change once specific information are available, information on accuracy level is provided for each species.
Code availability
All validation files, procedures and scripts are provided in Padovani and Borges52. All files are available in Unicode (UTF-8) format.
References
Klein, A. M. et al. Importance of pollinators in changing landscapes for world crops. Proc. R. Soc. B. 274, 303–313 (2007).
Ollerton, J. Pollinator diversity: distribution, ecological function, and conservation. Annu. Rev. Ecol. Evol. Syst. 48, 353–76 (2017).
Jaffé, R. et al. Bees for development: Brazilian survey reveals how to optimize stingless beekeeping. Plos One 10(3), e0130111 (2015).
Matias, D. M. S., Leventon, J., Rau, A., Borgemeister, C. & Wehrden, H. A review of ecosystem service benefits from wild bees across social contexts. Ambio 46, 456–467 (2017).
Winfree, R., Gross, B. J. & Kremen, C. Valuing pollination services to agriculture. Ecol. Econ. 71, 80–88 (2011).
Kleijn, D. et al. Delivery of crop pollination services is an insufficient argument for wild pollinator conservation. Nat. Commun. 6, 7414 (2015).
Steffan-Dewenter, I. & Westphal, C. The interplay of pollinator diversity, pollination services and landscape change. J. Appl. Ecol 45, 737–741 (2008).
Garibaldi, L. A. et al. Stability of pollination services decreases with isolation from natural areas despite honey bee visits. Ecol. Lett 14, 1062–1072 (2011).
Coutinho, J. G. E., Garibaldi, L. A. & Viana, B. F. The influence of local and landscape scale on single response traits in bees: A meta-analysis. Agric. Ecosyst. Environ 256, 61–73 (2018).
Hipolito, J. et al. Valuing nature’s contribution to people: The pollination services provided by two protected areas in Brazil. Glob. Ecol. Conserv. 20, e00782 (2019).
Potts, S. G., Biesmeijer, J. C., Kremen, C., Neumann, P., Schweiger, O. & Kunin, W. Global pollinator declines: trends, impacts and drivers. Trends Ecol. Evol. 25, 345–353 (2010).
Potts, S. G. et al. Safeguarding pollinators and their values to human well-being. Nature 540, 220–229 (2016).
Cardinale, B. J. et al. Biodiversity loss and its impact on humanity. Nature 486, 59–67 (2012).
Lichtenberg, E. M., Mendenhall, C. D. & Brosi, B. Foraging traits modulate stingless bee community disassembly under forest loss. J. Anim. Ecol. 86, 1404–1416 (2017).
Giannini, T. C. et al. Projected climate change threatens pollinators and crop production in Brazil. Plos One 12, e0182274 (2017).
Campbell, A. J. et al. Anthropogenic disturbance of tropical forests threatens pollination services to açaí palm in the Amazon river delta. J Appl. Ecol. 55, 1725–1736 (2018).
Larsen, T. H., Williams, N. M. & Kremen, C. Extinction order and altered community structure rapidly disrupt ecosystem functioning. Ecol. Lett 8, 538–547 (2005).
Gagic, V. et al. Functional identity and diversity of animals predict ecosystem functioning better than species-based indices. Proc. R. Soc. B. 282, 1–8 (2015).
Kissling, W. D. et al. Towards global data products of essential biodiversity variables on species traits. Nat. Ecol. Evol 2, 1531–1540 (2018).
Carvalheiro, L. G. et al. Natural and within-farmland biodiversity enhances crop productivity. Ecol. Lett 14, 251–259 (2011).
Sydenham, M. A. K. et al. Community level niche overlap and broad scale biogeographic patterns of bee communities are driven by phylogenetic history. J. Biogeogr. 45, 461–472 (2018).
Fantinato, E., Vecchio, S. D., Giovanetti, M., Acosta, A. T. R. & Buffa, G. New insights into plants co-existence in species-rich communities: The pollination interaction perspective. J. Veg. Sci. 29, 6–14 (2018).
Armbruster, W. S. & Muchhala, N. Associations between floral specialization and species diversity: cause, effect, or correlation? Evol. Ecol. 23, 159–179 (2009).
Castilla, A. R. et al. Adding landscape genetics and individual traits to the ecosystem function paradigm reveals the importance of species functional breadth. PNAS 114, 12761–12766 (2017).
Kremen, C. et al. Pollination and other ecosystem services produced by mobile organisms: a conceptual framework for the effects of land-use change. Ecol. Lett. 10, 299–314 (2007).
Greenleaf, S. S., Williams, N. M., Winfree, R. & Kremen, C. Bee foraging ranges and their relationship to body size. Oecologia 153, 589–596 (2007).
Cariveau, D. P. et al. The allometry of bee proboscis length and its uses in ecology. Plos One 11, e0151482 (2016).
Kremen, C. Managing ecosystem services: what do we need to know about their ecology? Ecol. Lett 8, 468–479 (2005).
Bartomeus, I., Cariveau, D. P., Harrison, T. & Winfree, R. On the inconsistency of pollinator species traits for predicting either response to land‐use change or functional contribution. Oikos 127, 306–315 (2018).
Mori, A. S., Lertzman, K. P. & Gustafsson, L. Biodiversity and ecosystem services in forest ecosystems: a research agenda for applied forest ecology. J. Appl. Ecol. 54, 12–27 (2017).
McGill, B. J., Enquist, B. J., Weiher, E. & Westoby, M. Rebuilding community ecology from functional traits. Trends Ecol. Evol. 21, 178–185 (2006).
Michener, C. D. Bees of The World 2nd edn (The Johns Hopkins University Press, 2007).
Saturni, F. T., Jaffé, R. & Metzger, J. P. Landscape structure influences bee community and coffee pollination at different spatial scales. Agric. Ecosyst. Environ 235, 1–12 (2016).
Rader, R., Bartomeus, I., Tylianakis, J. M. & Laliberté, E. The winners and losers of land use intensification: pollinator community disassembly is non-random and alters functional diversity. Diversity Distrib 20, 908–917 (2014).
Aguirre-Gutiérrez, J. et al. Functional traits help to explain half-century long shifts in pollinator distributions. Sci. Rep 6, 24451 (2016).
Moure, J. S., Urban, D. & Melo, G. A. R. Catalogue of Bees (Hymenoptera, Apoidea) in the Neotropical Region, http://moure.cria.org.br/catalogue (2008).
Borges, R. C., Imperatriz-Fonseca, V. L. & Giannini, T. C. A_dataset_of_multi_functional_ecological_traits_of_Brazilian_bees.csv. figshare, https://doi.org/10.6084/m9.figshare.7100525.v4 (2018).
ter Steege, H. et al. Hyperdominance in the amazonian tree flora. Science 342, 1243092 (2013).
Viana, P. L. et al. Flora of the cangas of the Serra dos Carajás, Pará, Brazil: history, study area and methodology. Rodriguésia 67, 1107–1124 (2016).
Silveira, F. A., Melo, G. A. R. & Almeida, E. A. B. Abelhas brasileiras sistemática e identificação 1st edn (Belo Horizonte, 2002).
Santos, L. M. & Melo, G. A. R. Updating the taxonomy of the bee genus Megalopta (Hymenoptera: Apidae, Augochlorini) including revision of the Brazilian species. J. Nat. Hist 49, 575–674 (2015).
Almeida, E. A. B. & Gibran, N. S. Taxonomy of neopasiphaeine bees: review of tetraglossula ogloblin, 1948 (hymenoptera: colletidae). Zootaxa 4303, 521–544 (2017).
Smith, P. S., Heard, T. A., Beekman, M. & Gloag, R. Flight range of the Australian stingless bee Tetragonula carbonaria (Hymenoptera: Apidae). Austral Entomol 56, 50–53 (2017).
Campbell, A. J., Gomes, R. L. C., Silva, K. C. & Contrera, F. A. L. Temporal variation in homing ability of the neotropical stingless bee Scaptotrigona aff. postica (Hymenoptera: Apidae: Meliponini). Apidologie 50, 720–732 (2019).
Gathmann, A. & Tscharntke, T. Foraging ranges of solitary bees. J. Anim. Ecol. 71, 757–764 (2002).
Zurbuchen, A., Landert, L., Klaiber, J., Muller, A., Hein, S. & Dorn, S. Maximum foraging ranges in solitary bees: only few individuals have the capability to cover long foraging distances. Biol. Conserv. 143, 669–676 (2010).
Benjamin, F. R., Reilly, J. R. & Winfree, R. Pollinator body size mediates the scale at which land use drives crop pollination services. J. Appl. Ecol. 51, 440–449 (2014).
Wray, J. C., Neame, L. A. & Elle, E. Floral resources, body size, and surrounding landscape influence bee community assemblages in oak-savannah fragments. Ecol. Entomol. 39, 83–93 (2014).
Wright, I. R., Roberts, S. P. M. & Collins, B. E. Evidence of forage distance limitations for small bees (Hymenoptera: Apidae). Eur. J. Entomol. 112, 303–310 (2015).
Giannini, T. C. et al. Climate change in the Eastern Amazon: crop-pollinator and occurrence-restricted bees are potentially more affected. Reg. Environ. Change 20, 1–12 (2020).
Giannini, T. C. et al. Crop pollinators in Brazil: a review of reported interactions. Apidologie 46, 209–223 (2015).
Padovani, K. & Borges, R. A dataset of multi-functional ecological traits of Brazilian bees (data validation). Open Science Framework https://doi.org/10.17605/OSF.IO/CMJVX (2020).
Acknowledgements
We thank to CNPq (446167/2015-0; 443254/2015-0; 381626/2016-4; 380846/2017-9, 381296/2018-0, 380762/2018-8, 373408/2019-6, 381187/2019-5); to Orlando T. Silveira and Beatriz W.T. Coelho at Museu Paraense Emílio Goeldi; to Fernando A. Silveira, Kirsten Lica Follmann Haseyama, Alessandro Lima, José Eustaquio dos Santos Júnior and Fernanda Trancoso of the Universidade Federal de Minas Gerais; to Rafael Melo de Brito, Carlos Eduardo Pinto da Silva, Luciano Costa, Ulysses Maia Madureira, Luiza Romeiro and Eder C. M. Lanes from the Instituto Tecnológico Vale; to Tiago Mahlman e Marcio Oliveira from Instituto Nacional de Pesquisa da Amazônia; and Sergio Dias, Letícia Guimarães and Alexandre Castilho from Vale S.A. We also thank to Rob Lanfear, Veronique van den Berghe and three anonymous reviewers for their comments and contributions for the final version of this manuscript. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES - Finance Code 001).
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R.C.B. and T.C.G. conceived the idea, compiled the data and wrote the first version of the manuscript. R.C.B. and K.P. revised, corrected and validated all datasets. R.C.B. and T.C.G. wrote the final version of the manuscript. All authors contributed substantially to the revision process and approved the final draft of the submitted manuscript.
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Borges, R.C., Padovani, K., Imperatriz-Fonseca, V.L. et al. A dataset of multi-functional ecological traits of Brazilian bees. Sci Data 7, 120 (2020). https://doi.org/10.1038/s41597-020-0461-3
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DOI: https://doi.org/10.1038/s41597-020-0461-3
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